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The Spatial Relations of Genes
Author: A. H. Sturtevant
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"168 GENETICS: STURTEVANT, BRIDGES, AND MORGAN give a crossing over percentage of 35% or more no increase at all results.A summary of these facts extracted from my earlier paper is given below. The percentage of increase over the control is given. Only those data which were collected at the same time are entirely comparable with each other. As a whole this table shows conclusively that small percentages of crossing over are increased markedly by high or low temperatures, while larger per-centages show a much less significant increase. For instance, as a result ofexposure of the F1 females to 32�C. (no. 7 in the table) the crossing over value between black and purple was increased from 6 in the control to 15.7-an increase of 162%-while purple-curved in the same experiment showed an increase from 19.6 to 26.5 or only 35%. In no. 9 in the table it is shown that while the black-curved value was increased by 58% as a result of a tem-perature of 31.5�C., the value of the star to black region (38.4 units) not only did not increase, but actually showed a slight decrease. The amount of the increase is in all cases related to the crossover value involved. The last named case was explained in my former paper as follows (p. 157): The first brood data show very clearly that while the blackcurved region of the chromo- some shows an unquestionable increase of more than 50%, no increase at all is registered in the test between star and black. This can mean only that with such long distances any increase in the actual amount of single crossing over is compensated by a similar increase in double crossing over, and thus no increase at all appears in the percentage registered by the count. The data show that the percentage of increase caused by high or low temperature is roughly in inverse proportion to the size of the crossover valueinvolved. On Castle's three dimensional scheme these facts necessitate the view that long chromosomal 'distances' are less affected by temperature than are short ones. On the hypothesis of linear arrangement this relation is consistently explained by the assumption that the amount of doublecrossing over is increased by high and by low temperatures. 1 Plough, H. H., J. Exp. Zool., 24, 1917, (147).'Bridges, C. B., Ibid., 19, 1915, (1). THE SPATIAL RELATIONS OF GENES BY A. H. STURTEVANT, C. B. BRIDGES, AND T. H. MORGAN COLUMBIA UNIVEsrrY AND CARNEGIE INSTITUTION OF WASHINGTON Communicated April 11, 1919 Castle1 has proposed an arrangement of linked genes in three dimensions, based on the assumption that the distance between any two loci is exactlyproportional to the observed crossover value. He believes that this systemgives a better agreement between observation and expectation than does thehypothesis of a strictly linear arrangement that we have developed. GENETICS: STURTEVANT, BRIDGES, AND MORGAN According to Castle, "that the arrangement of the genes within a linkagesystem is strictly linear seems for a variety of reasons doubtful." The only one of these reasons specified is that "it is doubtful, for example, whether an elaborate organic molecule ever has a simple string-like form." The sugges- tion that chromosomes are organic molecules is probably not intended to be taken seriously. The further argument, that organic molecules probably never have a simple string-like form, is scarcely to the point, for chromosomes do have a thread-like form. The comparison between crossing over andorganic substitution reactions seems forced, for these reasons, as well as onstrictly chemical grounds. Castle presents two cases as "critical" ones showing that the arrangement cannot be linear; viz., the relations of bifid and of abnormal to yellow and white. The case of abnormal presents some complications,2 but bifid may beaccepted as a crucial case. On the basis of the data summarized by Morgan and Bridges3 and used by Castle, the crossover values for yellow, white and bifid are: Yellow white.......................................................... 1.1 White bifid............................................................ 5.3 Yellow bifid . ..................................... .................. 5.5 Each of these values is based on several thousand flies, so that the probable errors arising from random sampling are small. Castle points out that no one of the three values is either the sum or the difference of the other two, and therefore concludes that the placing of the three loci in a line cannotrepresent their relations to each other. But these data come from several sources; and it has frequently been pointed out that crossover values aresubject to variation, due to genetic factors,4 to environmental causes,6 or to differential viability.6 In such a case as the present one, then, strictly com- parable data can be obtained only from experiments in which all three lociare followed at the same time.7 Such crucial data for yellow, white, and bifid had been given by Morgan and Bridges3 and by Muller,4 in papers which were known to Castle. These experiments may be summarized as follows: YELLOW NON-CROSS- SEPARATES WITE BIFID OVERS FROM OTHER SEPARATES SEPARATES TWO Morgan and Bridges................ 487 3 0 16 506Muller............................ 673 12 0 27 712 Total........................... 1160 15 0 43 1218 Percentage..................... 1.2 0.0 3.5 Here we have crossover values that are strictly comparable with each other, and they show: 169 170 GENETICS: STURTEVANT, BRIDGES, AND MORGAN Yellow white....................................................... . 1.2 White bifid................. ................ .......... 3.5 Yellow bifid........................................................... 4.7 These relations, in which the sum of the smaller values is exactly equal to the larger one, can be represented8 only by placing the three loci in a straightline, in the order yellow, white, bifid.9 It will be seen that this linear arrangement is necessitated by the fact that white never separated from yellow and bifid; i.e., no 'double crossover' occurred. By considering data involving only short distances (e.g., white bifid club, bifid club vermilion, club vermilion miniature, vermilion miniature sable, sable rudimentary forked, rudimentary forked bar, and forked barfused; or still better, certain unpublished data including the loci ruby, cut, tan, garnet, etc.), it is possible to handle the whole X-chromosome of Droso-phila as made up of successive overlapping sections in which double crossing over either does not occur or is so rare as to be negligible. Since these sec- tions must be represented as straight lines, and since they overlap, the whole X-chromosome must be represented as a straight line. For longer sections of this same chromosome, however, double crossovers do occur, so that the distances apart on the straight line are no longer pro-portional to the crossover values. The 'map-distance' for white forked, forexample, is 55.4, though the crossover value observed10 is 43.9. Castle is disturbed by such map distances greater than 50. He says: "A crossover value greater than fifty cannot exist. For there must be eitherlinkage or no-linkage. But no-linkage means 50% crossovers, and linkage means less than 50% crossovers. Hence a value greater than 50% cannot occur." It is evident that the conclusion of this curious syllogism dependssolely on the definition of linkage contained in the second half of the secondpremise. It is true that crossover values.significantly greater than fifty have never been found, but this is due to the frequency of double crossovers-to the fact that 'coincidence' is high for long distances. But coincidence is known to be a variable quantity, so that there would seem to be no a priori reason to suppose that crossover values greater than fifty are impossible. Further- riore, as has been explained above, map distances greater than 50 have neverbeen intended to represent observed crossover values greater than fifty. It is to be observed that the three dimensional figure given by Castle might seem capable of reduction to a curved.line lying in one plane. An exami- nation of his figure 2 shows that the only loci far from the plane that includes most of the group are bifid, depressed, shifted, lethal 3, furrowed, and lethal sc. Let us then examine these individually. Bifid has already been shown to lie in the same straight line with yellow and white, both of which are in Castle's thickly populated plane. Morgan and Bridges give three crossover values for depressed, two ofwhich (white depressed and depressed vermilion) are stated to be based on 59 GENETICS: STURTEVANT, BRIDGES, AND MORGAN flies each. Such meager data are clearly insufficient to establish accurate crossover values. But the values given by Morgan and Bridges are them- selves incorrect, as is shown by their account of the actual experiment (p. 68). The total number of flies is 69, not 59, and the crossover values accordingly become 17.4 for white depressed (instead of 20.3) and 14.5 for depressed ver- milion (instead of 17.0). The sum of these values, 31.9, is not significantly different from 30.5, the accepted value for white vermilion. This relation, and the fact that the 69 flies included no double crossover, give no warrant for supposing that the locus of depressed is outside of the plane that includes white, vermilion, and bar.Only two crossover values are given for shifted-shifted vermilion and shifted bar. Itf is evidently impossible to place a point in space by means of its distances from only two other points. Three are necessary, as Castle himself points out in connection with abnormal and bifid. There is thus no reason whatever for placing shifted out of the common plane. The aberrant position of lethal 3 in Castle's model is evidently due in large part to the fact, shown by Morgan and Bridges (p. 75), that the experimentsinvolving this locus gave a value of 2.3 for vermilion miniature, which is less than the mean value, 3.1, used by Castle. The values obtained in the lethal 3 experiments were: Lethal 3 vermilion................... ................................. 6.8 Vermilion miniature................................................... 2.3 Lethal 3 miniature .................. ........... ... ................ .... 9.3 The third value is substantially the same as the sum of the first two-hence the three loci must be represented as lying very nearly in a straight line. In the case of furrowed, the values are all based on a few flies (240 or less/ in every case), and the three most important values (vermilion furrowed, miniature furrowed, and furrowed sable) were all obtained in different experi- ments, so that comparisons are hazardous. Furrowed is a character that isoften difficult and sometimes impossible to classify, so that there is a large probability of error in the counts that have been reported.In the case of lethal sc there is only one available crossover value (bar lethal sc, 8.3) small enough so that double crossing over would be negligible; and there are no data involving lethal sc and more than one other locus at the same time. The data are therefore not of the type to give a decisive answer as to the relations of the locus. A careful examination of the data thus shows that a single plane suffices for the representation of the loci dealt with by Castle. Within this plane the positions of the remaining loci fall, in Castle's figure, roughly into a single curved line. The only noticeable exception is the locus of lemon. This locus is based on only 241 flies, and these gave rather too small a crossover value for the well established white vermilion distance, so that this discrepancy is notsignificant. The arrangement of the genes is thus approximately linear, but 171 172 GENETICS: STURTEVANT, BRIDGES, AND MORGAN the line is cuirved instead of straight. This curvature is due to the phenome- non of double crossing over, and the degree of curvature is dependent on thefrequency of double crossovers; i.e., upon 'coincidence.' This method ofrepresenting coincidence, however, leads to inconsistencies. As was pointedout above, it is possible to build up the whole X-chromosome from succes- sive overlapping sections, each of which is so short as to include few or no double crossovers. Yet double crossovers are not rare in longer sections. If ABC and BCD are sections so short that no double crossing over occurs within each, section ABCD may be long enough so that double crossing over in which one crossover is between A and B and the other between C and D may still occur; and in that case it becomes necessary to represent D in twopositions at the same time. Such situations are actually known in Droso- phila. Hence the curved line cannot give a consistent scheme; nor can anyother scheme based on the assumption that long distances, as well as short ones, are to be represented as proportional to observed percentages of crossing over.According to Castle the supposition that double crossovers do occur is "an unproved secondary hypothesis." Of course, if three genes are imagined asnot lying in a straight line, a single plane may separate any one from the other two. Under these conditions double crossing over has no meaning. But the fact remains that when three linked genes are studied simultaneously, one pair of contrary classes is always small, and this class is always the one that is the double crossover class on the linear arrangement scheme. Some method of accounting for the smallness of this class is evidently demanded. Castle recognizes this, and suggests that the explanation may be either that"only transverse breaks occur, of which two taking place simultaneously arerequired to produce the difficult regrouping" (i.e., the familiar double crossoverexplanation), or that "transverse breaks are more frequent than oblique longi- tudinal ones, of which a single one would suffice to accomplish the regrouping, if the genes are not strictly linear in arrangement." Muller4 has published data bearing on this point. He followed simultaneously eleven loci in the X-chromosome of Drosophila, and obtained some double crossover classes thataccording to Castle's model are impossible with a single plane. However, if the loci all reduce to the curved line discussed above, than any so-called double crossover is possible with a single separation plane. But those classes now termed triple and quadruple crossovers are all impossible with a single plane ofcrossing over. In the case of the X-chromosome over a dozen triple crossovers have been observed, and in the case of the second chromosome they are sofrequent that 131 were observed in a single experiment. It follows that, even if the genes are not arranged in a straight line, the occurrence of doublecrossing over is an established fact, not an unproved hypothesis. If crossover planes do not occur longitudinally, or occur thus less often thantransversely, it is difficult to see how the distances apart of the loci in Castle's model can be proportional to the crossover values, except in the case where PHYSICS: A. G. WEBSTER the line joining the loci is perpendicular to the average direction of crossoverplanes. The crossover value for lines in any other directions would seem to be proportional to their projections on such a perpendicular. In short, both of Castle's alternative subsidiary hypotheses to account for the rarity of double crossovers are inconsistent with his primary assumption that distances are proportional to crossover values. 1 These PROCEEDINGS, 5, 1919, (25). 2 Abnormal is a character that is separable from wild-type only under certain environ- mental conditions; and is also simulated by accidental abnormalities. It is, therefore, not a reliable character to use in linkage experiments. 8 Carnegie Inst., Washington, Pub., No. 237, 1916. 4 Sturtevant, these PROCEEDINGS, 3, 1917, (555), and Muller, Amer. Naturalist, FO, 1916, (193, 284, 350, 421).Bridges, J. Exp. Zool., 19, 1915, (1), and Plough, Ibid., 24, 1917, (147). Bridges and Sturtevant, Bio . Bull., 26, 1914, (205), and Morgan and Bridges, loc. cit.,note 3. 7That Castle tacitly recognized this is shown by the fact that he omitted lethal 2 from his model, without even mentioning the fact. It is obvious from an examination of the data in this case that the crossover values are inconsistent with those obtained in otherexperiments not involving lethal 2. 8 Provided the relations of the loci are to be represented by straight lines joining them and proportional in length to the corresponding crossover values. 9It does not follow that 4.7 is to be taken as the locus of bifid, for the mean value indi- cated by all bifid experiments is the one most likely to coincide with future experiments;i.e., to give the best predictions. 10 Castle concluded that the white forked value of 45.7, used by him, is somewhat too high, which is true; but there were available to him more than 40,000 flies (Bridges, Genetics, 1,1916, (1), and Weinstein, Ibid., 3, 1918, (135)) giving the lower value, in contrast to the less than 4000 flies on which the high value was based. A COMPLETE APPARATUS FOR ABSOLUTE ACOUSTICAL MEASUREMENTS BY ARTHUR GORDON WEBSTER CLARK UNIVERSITY, WORCESTER, MASS. Read before the Academy, November 17, 1915 The apparatus here briefly described is the result of researches begun many years ago in the attempt to solve the problem of measuring the intensity ofsound at any given point of space in terms of absolute units, by means of in- struments that may be reproduced from specifications, and that shall be con- venient and portable. For this purpose three things are requisite; first, a source of sound that shall continuously produce a simple tone of known in-tensity-this will be denoted by the term 'phone;' second, an instrument formeasuring in absolute units a constantly maintained simple tone, here called 173 "
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